Diese Präsentation wurde erfolgreich gemeldet.
Die SlideShare-Präsentation wird heruntergeladen. ×
Anzeige
Anzeige
Anzeige
Anzeige
Anzeige
Anzeige
Anzeige
Anzeige
Anzeige
Anzeige
Anzeige
Anzeige
Nächste SlideShare
Transportation in plants
Transportation in plants
Wird geladen in …3
×

Hier ansehen

1 von 13 Anzeige
Anzeige

Weitere Verwandte Inhalte

Diashows für Sie (20)

Ähnlich wie Aaa transport (20)

Anzeige

Aktuellste (20)

Aaa transport

  1. 1. Transport in plants • Transport in plants – Water and dissolved nutrients upwards from the roots – Carbohydrates produced in leaves to rest of plant How do organisms ‘solve’ common problems?
  2. 2. Transport in plants • How do plants transport carbohydrates? – Movement of carbohydrates through vascular system is called translocation • Carbohydrates produced in photosynthetic organs (usually leaves) and often stored in roots • Movement of carbohydrates is through phloem – Phloem consists of two types of cells: » Sieve cells: living cells stacked on top of each other » Sieve-tube members: similar to sieve cells but found only in angiosperms (flowering plants) How do organisms ‘solve’ common problems?
  3. 3. Transport in plants • How do plants transport carbohydrates? – Mass-flow or pressure-flow hypothesis: • Carbohydrates move from source (site produced or stored) to sink (site used) – Carbohydrates actively transported into phloem at source – High concentration of carbohydrates causes greater osmotic pressure in phloem; water moves in from adjacent xylem by osmosis – Water influx creates (turgor) pressure inside phloem; pushing water and dissolved carbohydrates through phloem – At sink, carbohydrates actively removed from phloem; reducing osmotic pressure in phloem – water leaves phloem and reenters xylem, maintaining a osmotic pressure gradient between sources and sinks How do organisms ‘solve’ common problems?
  4. 4. Transport in plants • How do plants transport carbohydrates? – Mass-flow or pressure-flow hypothesis: How do organisms ‘solve’ common problems?
  5. 5. Transport in plants • Nutrients required by plants – Macronutrients (required in relatively large amounts) • 9 macronutrients including: – Nitrogen – Phosphorus Fertilizer numbers (e.g.10-15-10) – Potassium refer to these macronutrients – Micronutrients (required in trace amounts) • 7 micronutrients including: – Chlorine – Iron – Manganese How do organisms ‘solve’ common problems?
  6. 6. Transport in plants • Nutrients required by plants – Most nutrients needed by plants obtained from soil • Most roots found in topsoil – Mineral particles (nutrients) – Living organisms (particularly detritivores) – Humus (partly decayed organic matter) • Some plants in acidic bogs obtain Nitrogen by trapping and digesting insects (e.g. Venus flytrap) • Legumes house Nitrogen-fixing bacteria in root nodules • Most plants have mycorrhizal fungi that enhance nutrient uptake by increasing surface area of ‘roots’ How do organisms ‘solve’ common problems?
  7. 7. Transport in plants • How do plants get nutrients and water into roots? – Water ‘absorbed’ by root hairs (projections of epidermis cells) – Root hairs greatly increase surface area over which to ‘absorb’ water – Root hairs have greater osmotic potential than soil • osmotic (or solute) potential = pressure that must be applied to stop osmosis • Root cells actively pump ions (use ATP) into cells High concentration of ions creates a greater osmotic pressure in plant than surrounding soil water; water moves into cells by osmosis • How do organisms ‘solve’ common problems?
  8. 8. Transport in plants • How do plants get nutrients and water into vascular system of roots? – Water and ions enter root hairs and move between or through membranes of cells of cortex – Casparian strips block water movement; force water through cell membranes of endoderm – Endodermal cells selects nutrients that enter vascular tissue (xylem) How do organisms ‘solve’ common problems?
  9. 9. Transport in plants • How do plants get nutrients and water up xylem? – Xylem includes 2 types of dead, hollow, tubular cells • Vessel members: slightly large diameter; cells stacked • Tracheids: smaller diameter; side to side overlap – Vessel members only occur in angiosperms (flowering plants) How do organisms ‘solve’ common problems?
  10. 10. Transport in plants • How do plants get nutrients and water up xylem? – Water molecules sticks to walls of xylem (adhesion) and to each other (cohesion) – Water moves through xylem in unbroken column – Air on leaf surfaces causes water to evaporate, creating a ‘pull’ on the water column • Essentially, osmotic pressure of air is greater than osmotic pressure within leaves • Process of evaporative water loss in plants is called transpiration How do organisms ‘solve’ common problems?
  11. 11. Transport in plants • Transpiration – 90% of water ‘absorbed’ by roots lost through transpiration in leaves • Transpiration through stomata, pores in epidermis of leaves • Transpiration rate regulated by two guard cells surrounding each stoma (or stomate) How do organisms ‘solve’ common problems?
  12. 12. Transport in plants • Transpiration – Action of guard cells • Guard cells open when water moves into cells by osmosis (i.e. cells are turgid) – Turgor results from active uptake of Potassium (K+) ions; and subsequent influx of water by osmosis How do organisms ‘solve’ common problems?
  13. 13. Transport in plants • Conflicting requirements of plants – Water lost by transpiration through stomata – But water needed for metabolic activity such as photosynthesis – If plants prevent water loss by closing guard cells then no CO 2 can enter for photosynthesis • How do plants solve the conflict? • Surprise, surprise … different plants have different solutions – First, a review of photosynthesis... How do organisms ‘solve’ common problems?

×